src/parsec/disk-image/parsec/parsec-benchmark/pkgs/libs/gsl/src/eigen/herm.c - public/gem5-resources - Git at Google

 /* eigen/herm.c
  *
  * Copyright (C) 2001 Brian Gough
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License as published by
  * the Free Software Foundation; either version 2 of the License, or (at
  * your option) any later version.
  *
  * This program is distributed in the hope that it will be useful, but
  * WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  * General Public License for more details.
  *
  * You should have received a copy of the GNU General Public License
  * along with this program; if not, write to the Free Software
  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
  */

 #include <config.h>
 #include <stdlib.h>
 #include <gsl/gsl_math.h>
 #include <gsl/gsl_vector.h>
 #include <gsl/gsl_matrix.h>
 #include <gsl/gsl_linalg.h>
 #include <gsl/gsl_eigen.h>

 /* Compute eigenvalues of complex hermitian matrix using reduction to
    real symmetric tridiagonal form, followed by QR iteration with
    implicit shifts.

    See Golub & Van Loan, "Matrix Computations" (3rd ed), Section 8.3 */

 #include "qrstep.c"

 gsl_eigen_herm_workspace *
 gsl_eigen_herm_alloc (const size_t n)
 {
   gsl_eigen_herm_workspace * w ;

   if (n == 0)
     {
       GSL_ERROR_NULL ("matrix dimension must be positive integer", GSL_EINVAL);
     }

   w = (gsl_eigen_herm_workspace *) malloc (sizeof(gsl_eigen_herm_workspace));

   if (w == 0)
     {
       GSL_ERROR_NULL ("failed to allocate space for workspace", GSL_ENOMEM);
     }

   w->d = (double *) malloc (n * sizeof (double));

   if (w->d == 0)
     {
       GSL_ERROR_NULL ("failed to allocate space for diagonal", GSL_ENOMEM);
     }

   w->sd = (double *) malloc (n * sizeof (double));

   if (w->sd == 0)
     {
       GSL_ERROR_NULL ("failed to allocate space for subdiagonal", GSL_ENOMEM);
     }

   w->tau = (double *) malloc (2 * n * sizeof (double));

   if (w->tau == 0)
     {
       GSL_ERROR_NULL ("failed to allocate space for tau", GSL_ENOMEM);
     }

   w->size = n;

   return w;
 }

 void
 gsl_eigen_herm_free (gsl_eigen_herm_workspace * w)
 {
   free (w->tau);
   free (w->sd);
   free (w->d);
   free(w);
 }

 int
 gsl_eigen_herm (gsl_matrix_complex * A, gsl_vector * eval,
                      gsl_eigen_herm_workspace * w)
 {
   if (A->size1 != A->size2)
     {
       GSL_ERROR ("matrix must be square to compute eigenvalues", GSL_ENOTSQR);
     }
   else if (eval->size != A->size1)
     {
       GSL_ERROR ("eigenvalue vector must match matrix size", GSL_EBADLEN);
     }
   else
     {
       const size_t N = A->size1;
       double *const d = w->d;
       double *const sd = w->sd;

       size_t a, b;

       /* handle special case */

       if (N == 1)
         {
           gsl_complex A00 = gsl_matrix_complex_get (A, 0, 0);
           gsl_vector_set (eval, 0, GSL_REAL(A00));
           return GSL_SUCCESS;
         }

       {
         gsl_vector_view d_vec = gsl_vector_view_array (d, N);
         gsl_vector_view sd_vec = gsl_vector_view_array (sd, N - 1);
         gsl_vector_complex_view tau_vec = gsl_vector_complex_view_array (w->tau, N-1);
         gsl_linalg_hermtd_decomp (A, &tau_vec.vector);
         gsl_linalg_hermtd_unpack_T (A, &d_vec.vector, &sd_vec.vector);
       }

       /* Make an initial pass through the tridiagonal decomposition
          to remove off-diagonal elements which are effectively zero */

       chop_small_elements (N, d, sd);

       /* Progressively reduce the matrix until it is diagonal */

       b = N - 1;

       while (b > 0)
         {
           if (sd[b - 1] == 0.0 || isnan(sd[b - 1]))
             {
               b--;
               continue;
             }

           /* Find the largest unreduced block (a,b) starting from b
              and working backwards */

           a = b - 1;

           while (a > 0)
             {
               if (sd[a - 1] == 0.0)
                 {
                   break;
                 }
               a--;
             }

           {
             const size_t n_block = b - a + 1;
             double *d_block = d + a;
             double *sd_block = sd + a;

             /* apply QR reduction with implicit deflation to the
                unreduced block */

             qrstep (n_block, d_block, sd_block, NULL, NULL);

             /* remove any small off-diagonal elements */

             chop_small_elements (n_block, d_block, sd_block);
           }
         }

       {
         gsl_vector_view d_vec = gsl_vector_view_array (d, N);
         gsl_vector_memcpy (eval, &d_vec.vector);
       }

       return GSL_SUCCESS;
     }
 }
	/* eigen/herm.c
	*
	* Copyright (C) 2001 Brian Gough
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License as published by
	* the Free Software Foundation; either version 2 of the License, or (at
	* your option) any later version.
	*
	* This program is distributed in the hope that it will be useful, but
	* WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	* General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with this program; if not, write to the Free Software
	* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
	*/

	#include <config.h>
	#include <stdlib.h>
	#include <gsl/gsl_math.h>
	#include <gsl/gsl_vector.h>
	#include <gsl/gsl_matrix.h>
	#include <gsl/gsl_linalg.h>
	#include <gsl/gsl_eigen.h>

	/* Compute eigenvalues of complex hermitian matrix using reduction to
	real symmetric tridiagonal form, followed by QR iteration with
	implicit shifts.

	See Golub & Van Loan, "Matrix Computations" (3rd ed), Section 8.3 */

	#include "qrstep.c"

	gsl_eigen_herm_workspace *
	gsl_eigen_herm_alloc (const size_t n)
	{
	gsl_eigen_herm_workspace * w ;

	if (n == 0)
	{
	GSL_ERROR_NULL ("matrix dimension must be positive integer", GSL_EINVAL);
	}

	w = (gsl_eigen_herm_workspace *) malloc (sizeof(gsl_eigen_herm_workspace));

	if (w == 0)
	{
	GSL_ERROR_NULL ("failed to allocate space for workspace", GSL_ENOMEM);
	}

	w->d = (double ) malloc (n sizeof (double));

	if (w->d == 0)
	{
	GSL_ERROR_NULL ("failed to allocate space for diagonal", GSL_ENOMEM);
	}

	w->sd = (double ) malloc (n sizeof (double));

	if (w->sd == 0)
	{
	GSL_ERROR_NULL ("failed to allocate space for subdiagonal", GSL_ENOMEM);
	}

	w->tau = (double ) malloc (2 n * sizeof (double));

	if (w->tau == 0)
	{
	GSL_ERROR_NULL ("failed to allocate space for tau", GSL_ENOMEM);
	}

	w->size = n;

	return w;
	}

	void
	gsl_eigen_herm_free (gsl_eigen_herm_workspace * w)
	{
	free (w->tau);
	free (w->sd);
	free (w->d);
	free(w);
	}

	int
	gsl_eigen_herm (gsl_matrix_complex * A, gsl_vector * eval,
	gsl_eigen_herm_workspace * w)
	{
	if (A->size1 != A->size2)
	{
	GSL_ERROR ("matrix must be square to compute eigenvalues", GSL_ENOTSQR);
	}
	else if (eval->size != A->size1)
	{
	GSL_ERROR ("eigenvalue vector must match matrix size", GSL_EBADLEN);
	}
	else
	{
	const size_t N = A->size1;
	double *const d = w->d;
	double *const sd = w->sd;

	size_t a, b;

	/* handle special case */

	if (N == 1)
	{
	gsl_complex A00 = gsl_matrix_complex_get (A, 0, 0);
	gsl_vector_set (eval, 0, GSL_REAL(A00));
	return GSL_SUCCESS;
	}

	{
	gsl_vector_view d_vec = gsl_vector_view_array (d, N);
	gsl_vector_view sd_vec = gsl_vector_view_array (sd, N - 1);
	gsl_vector_complex_view tau_vec = gsl_vector_complex_view_array (w->tau, N-1);
	gsl_linalg_hermtd_decomp (A, &tau_vec.vector);
	gsl_linalg_hermtd_unpack_T (A, &d_vec.vector, &sd_vec.vector);
	}

	/* Make an initial pass through the tridiagonal decomposition
	to remove off-diagonal elements which are effectively zero */

	chop_small_elements (N, d, sd);

	/* Progressively reduce the matrix until it is diagonal */

	b = N - 1;

	while (b > 0)
	{
	if (sd[b - 1] == 0.0 \|\| isnan(sd[b - 1]))
	{
	b--;
	continue;
	}

	/* Find the largest unreduced block (a,b) starting from b
	and working backwards */

	a = b - 1;

	while (a > 0)
	{
	if (sd[a - 1] == 0.0)
	{
	break;
	}
	a--;
	}

	{
	const size_t n_block = b - a + 1;
	double *d_block = d + a;
	double *sd_block = sd + a;

	/* apply QR reduction with implicit deflation to the
	unreduced block */

	qrstep (n_block, d_block, sd_block, NULL, NULL);

	/* remove any small off-diagonal elements */

	chop_small_elements (n_block, d_block, sd_block);
	}
	}

	{
	gsl_vector_view d_vec = gsl_vector_view_array (d, N);
	gsl_vector_memcpy (eval, &d_vec.vector);
	}

	return GSL_SUCCESS;
	}
	}